Printed Ink Structure using Fluoropolymer Template

ABSTRACT

A method is provided for controlling printed ink horizontal. cross-sectional areas using fluoropolymer templates. The method initially forms a fluoropolymer template overlying a substrate. The fluoropolymer template has a horizontal first cross-sectional dimension. Then, a primary ink is printed overlying the fluoropolymer template having a horizontal second cross-sectional dimension less than the first cross-sectional dimension. In the case of a fluoropolymer line having a template length greater than a template width, where the template width is the first cross-sectional dimension, printing the primary ink entails printing a primary ink line having an ink length greater than an ink width, where the ink width is the second cross-sectional dimension. In one aspect, the method prints a plurality of primary ink layers, each primary ink layer having an ink width less than the template width. Each overlying primary ink layer can be printed prior to solvents in underlying primary ink layers evaporating.

RELATED APPLICATIONS

This application is a Divisional of a patent application entitled,CONTROLLED PRINTED INK LINE WIDTHS USING FLUOROPOLYMER TEMPLATES,invented by Kurt Ulmer et al., Ser. No. 13/432,855, filed Mar. 28, 2012,which is incorporated herein by reference.

BACKGROUND OF THE INVENTION

1. Field of the Invention

This invention generally relates to integrated circuit (IC) fabricationand, more particularly, to a method for controlling printed ink linewidths using fluoropolymer templates.

2. Description of the Related Art

Printed electronics fabrication relies on the application of metalprecursor ink formulations to produce conductive circuit elements. Thesemetal precursor inks are applied to a substrate by inkjet printing forexample, and further processing steps are required to render the printedpattern conductive. Printed metal inks, however, produce conductivelines that have conductivities that are typically on the order of 10×less conductive than bulk metals or vacuum processed thin film metallayers. This inferior conductivity is detrimental to circuit design. Theconductivity limitations of these materials can be traced to densitylimitations due to voids and film porosity, as well as grain size andinterface effects. These detrimental effects can be reduced byincreasing annealing time and temperatures. However, substrate and hightemperature incompatibility of other thin film layers typicallyconstrain the annealing time/temperature conditions that are suitable.For these reasons, increasing the conductivity of printed metal lines ischallenging.

One means of increasing the conductance of a printed line is byincreasing the cross-sectional area of that line. This result can beachieved by increasing the width and/or the height of the line. Anincrease of the width of a conductive line is not typically preferredbecause that line will consume more substrate area and result in fewercircuits that can be physically placed on a given substrate. Increasingthe height of a printed line is conventionally the method used toincrease conductance. However, with solution process, and printedconductive lines in particular, this is not easily achieved. Printingthicker lines by applying more ink or printing multiple passes of inktypically results in thicker lines, but also wider lines as the inktends to spread on the substrate.

It would be advantageous if there was a method that added significantthickness to a printed conductive line, without an increase in linewidth.

SUMMARY OF THE INVENTION

Disclosed herein is a method for adding significant thickness to aprinted conductive line, without an increase in line width, byintroducing a printed fluoropolymer bank structure. The printed lineconductance is increased as a result of increasing the printed metalline thickness. Printed metal line thickness is increased without anincrease in the printed metal line width by using a fluoropolymer bankstructure that when fully processed is capable of limiting the lateralspread of the conductive metal precursor ink and enabling the use oflarger volumes of this metal ink.

Accordingly, a method is provided for controlling printed ink horizontalcross-sectional areas using fluoropolymer templates. The methodinitially forms a fluoropolymer template overlying a substrate. Thefluoropolymer template has a horizontal first cross-sectional dimension.Then, a primary ink is printed overlying the fluoropolymer templatehaving a horizontal second cross-sectional dimension less than the firstcross-sectional dimension. In the case of a fluoropolymer line having atemplate length greater than a template width, where the template widthis the first cross-sectional dimension, printing the primary ink entailsprinting a primary ink line having an ink length greater than an inkwidth, where the ink width is the second cross-sectional dimension.

In one aspect, the method prints a plurality of primary ink layers, eachprimary ink layer having an ink width less than the template width.Advantageously, each overlying primary ink layer can be printed prior tosolvents in each underlying primary ink layer evaporating. Printing theplurality of primary ink layers causes an increase in the verticalaverage height of the combined layer ink line following the printing ofeach successive primary ink layer. Further, the printing of eachsuccessive primary ink layer includes increases the average heightwithout increasing the ink width.

Additional details of the above-described method and a printed inkstructure with a controlled horizontal cross-sectional area are providedbelow.

BRIEF DESCRIPTION OF THE DRAWINGS

FIGS. 1A and 1B are, respectively, partial cross-sectional and planviews of a printed ink structure with a controlled horizontalcross-sectional area.

FIGS. 2A and 2B are, respectively, partial cross-sectional and planviews of a printed ink line structure.

FIG. 3 is a partial cross-section view of the printed ink line structureof FIG. 2, where the primary ink line is formed from a plurality ofprimary ink layers.

FIG. 4 depicts an ink drop formation on a substrate defined by theinteraction of three interfaces.

FIGS. 5A and 5B respectively depict the spread of ink on a substratewith high and low surface energy.

FIG. 6 is a partial cross-sectional representation of the printed bankstructures and printed metal lines produced by the methods describedabove.

FIG. 7 is a top down representation of an optical image of the printedmetal lines described in FIG. 6.

FIG. 8 is a diagram depicting printed metal line thickness profilemeasurements made with a Tencor stylus profilometer.

FIG. 9 is a graph depicting the average line thickness for each of theprofiles of FIG. 8, as determined by stylus profilometry. FIG. 10 is agraph depicting electrical resistance as measured by a 2-point probetechnique for 6, 10, and 15 print layers of silver

FIG. 11 is a flowchart illustrating a method for controlling printed inkhorizontal cross-sectional areas using fluoropolymer templates.

DETAILED DESCRIPTION

FIGS. 1A and 1B are, respectively, partial cross-sectional and planviews of a printed ink structure with a controlled horizontalcross-sectional area. The printed ink structure 100 comprises asubstrate 102 and a fluoropolymer template 104 overlying the substrate102. The fluoropolymer template 104 has a horizontal firstcross-sectional dimension 106. A primary ink structure 108 overlies thefluoropolymer template and has a horizontal second cross-sectionaldimension 110 less than the first cross-sectional dimension 106. in someaspects as shown, the fluoropolymer template 104 has a coffee stainpattern in the first cross-sectional dimension 106. As used herein, acoffee stain pattern is understood to a film of material with a greaterthickness of material around the edge of the pattern than in the center.In other words, a coffee stain pattern resembles a pattern of spilledcoffee underlying a coffee cup, after the coffee has dried. However, itshould be understood that the smaller horizontal cross-sectional area ofthe primary ink structure is not necessarily dependent upon a coffeestain shape formed in the template 104. In some aspect, thefluoropolymer template does not have a coffee stain pattern. FIGS. 1Aand 2B, as well as the drawings described below, are not necessarilydrawn to scale.

FIGS. 2A and 2B are, respectively, partial cross-sectional and planviews of a printed ink line structure. In this aspect, the fluoropolymertemplate 104 has a template length 200 greater than a template width,where the template width is the first cross-sectional dimension 106. Theprimary ink structure 108 has an ink length 202 greater than an inkwidth, where the ink width is the second cross-sectional dimension 110.

FIG. 3 is a partial cross-section view of the printed ink line structureof FIG. 2, where the primary ink line is formed from a plurality ofprimary ink layers 300-0 through 300-n. Each primary ink layer 300 hasan ink width 110 less than the template width 106. The vertical averageheight 302-n of primary ink layer 300-n is greater than the averageheight 302-(n−1) of primary ink layer 300-(n−1). Further, the ink width110 of primary ink layer 300-n is equal to the ink width 110 of primaryink layer 300-(n−1). In some aspects, see FIG. 8, a coffee stain.pattern exists in the primary ink layers, and the coffee stain patternin primary ink layer 300-n is more pronounced than the coffee stainpattern primary ink layer 300-(n−1). If the printed ink structure isformed from conductive ink layers, then a conductive printed linestructure of n conductive ink layers would have a higher electricalconductance than a conductive printed line structure of (n−1) conductiveink layers.

Functional Description

The coffee staining behavior of the printed fluoropolymer bank materialis of interest, as it is that behavior that creates the high sidewallsthat define the well in the hank structure that enables, with otherfactors, the containment of the printed metal precursor ink.

FIG. 4 depicts an ink drop formation on a substrate defined by theinteraction of three interfaces. The Evaporation Rate DistributionTheory by Deegan et al. ascribes the coffee stain pattern formation to“a form of capillary flow in which pinning of the contact line of thedrying drop ensures that liquid evaporating from the edge is replenishedby liquid from the interior.” The evaporative flux is shown to berelated to the pinned drop radius and the distance from drop center by:

J(r)∝(R _(f) −r)^(−λ); λ=(π−2θ_(c))/(2π−2θ_(c))

Where: J(r), evaporative flux

R_(f), final radius of dried drop

r, distance from center of drop

θ_(c), contact angle

Accordingly, at contact angles θ_(c)<π/2, J(r) becomes large at the edgeof the drying drop. With the limitation that the edge of the ink drop ispinned and that the ink drop diameter will not shrink in time, a flow ofliquid is established to replenish the liquid evaporating at arelatively higher rate at the edges. Solutes are carried with the flowof solvent toward the edge and a build-up of material is observed in atypical coffee stain pattern.

Also important is the low surface tension of the fluoropolymer bankmaterial that creates a high contact angle with the metal precursor ink,This behavior is described by Young's equation. The formation of adroplet on a solid surface is determined by the relative values ofenergies of the solid surface, surface tension of the liquid drop, andthe interface between the liquid and the solid surface. This behavior isdescribed by Young's Equation:

γ_(LV) cos θ_(c)=γ_(SV)−γ_(SL)

Where: γ_(LV), surface energy of the liquid droplet

γ_(SV), surface energy of the substrate

γ_(SL), surface energy of the substrate/liquid interface

θ_(c), contact angle

FIGS. 5A and 5B respectively depict the spread of ink on a substratewith high and low surface energy. A substrate with a relatively largesurface energy γ_(SL), compared to the surface tension of the inkdroplet γ_(LV) manifests itself as a significant spread of the inkdroplet on the substrate (FIG. 5A). A substrate with a small surfaceenergy will produce minimal ink droplet spread (FIG. 5B).

Thus, the fluoropolymer bank structure described above may haverelatively high edges due to coffee staining of the fluoropolymersolution and a low surface tension that can be used to contain aconductive precursor ink. The amorphous fluoropolymer coating solutionused in demonstration of the bank structure was AF1600 produced byDuPont. The AF1600 is diluted with the fluorosolvent FC-40 produced by3M Corporation. AF1600 was mixed with FC-40 at a ratio of 1:5 to form asolution suitable for inkjet printing. This diluted solution wasinjected into an empty Dimatix inkjet cartridge. Lines of AF1600 wereprinted using a Dimatix 2800 DMP materials printer onto a glasssubstrate that had been previously coated with a polymeric dielectriccoating. The printed fluoropolymer bank structures were thermally curedon a hotplate at 120° C. for 30 minutes.

The conductive ink used in demonstration was a silver nanoparticle inkformulation designated Sunjet U5603 produced by Sun ChemicalCorporation. The silver ink was injected into an empty Dimatix inkjetcartridge. Lines of silver nanoparticle ink were printed using a Dimatix2800 DMP materials printer. Multiple layers of the silver nanoparticleink were printed consecutively to demonstrate the ability of thefluoropolymer bank structures to contain varying volumes of conductiveink. All lines of ink were printed before thermal processing. Theprinted silver nanoparticle lines were thermally cured on a hotplate at120° C. for 30 minutes.

FIG. 6 is a partial cross-sectional representation of the printed bankstructures and printed metal lines produced by the methods describedabove. The bank structures as printed were approximately 200 microns(μm) wide and exhibited the coffee staining effect of drying inks thatmanifested itself in the case of printed lines as peaked structures atboth outer edges of the line. These peaks were measured to be about 100nanometers (nm) in height. This peak structure and the high contactangle of the fluoropolymer bank material acted to contain the silvernanoparticle ink that was subsequently printed into the well of the bankstructure. 6, 10, and 15 layers of silver nanoparticle ink were printedinto the fluoropolymer bank structures. These layers of ink weresequentially printed such that approximately 10 seconds elapsed betweeneach print. At this timescale, the solvent content of the ink from theprevious layers did not have time to fully evaporate before a subsequentlayer was added. Only at the end of all printing were the printed silverlines subjected to a thermal cure step that evaporated the solvents andsintered the silver nanoparticles together to form a conductive silverline. It can be seen that despite the difference in the number oflayers, the lines have the same width of 200 microns.

FIG. 7 is a top down representation of an optical image of the printedmetal lines described in FIG. 6. The line of the left side of the imagewas produced by printing 15 layers of silver nanoparticle ink into afluoropolymer bank structure. The line in the middle of the image wasproduced by printing 10 layers of silver nanoparticle ink, and 6 layersof silver nanoparticle ink in the line at the right side of the image.Each line has the same width; 200 μm. This width is determined by widthof the bank structure, the spread of the silver nanoparticle ink on thefluoropolymer material, and the bank structure's ability to limit thatspread.

FIG. 8 is a diagram depicting printed metal line thickness profilemeasurements made with a Tencor stylus profilometer. The widths of theprinted lines are the same in the cases of the 15, 10, and 6 layerprinted lines and corroborate the measurements taken by opticalmicroscopy. The thickness of the printed lines increases with anincrease in the number of printed layers. The coffee staining behaviorof the printed metal precursor ink itself is observed to be morepronounced with an increase in the number of printed layers.

FIG. 9 is a graph depicting the average line thickness for each of theprofiles of FIG. 8, as determined by stylus profilometry. A thicknessincrease in excess of 2× is observed between the 6 layer and 15 layerprint conditions. This confirms that the thickness of a printed metalline can be increased without lateral spread of the printed line byincorporation of a fluoropolymer bank structure.

FIG. 10 is a graph depicting electrical resistance as measured by a2-point probe technique for 6, 10, and 15 print layers of silvernanoparticle ink, Measured resistance is confirmed to decrease with anincrease in the number of printed metal layers. This confirms that theconductance of the printed metal line can be increased by increasing theprinted line thickness without lateral spread of the printed line byincorporation of a fluoropolymer bank structure.

Additionally, several silver lines were printed outside of the bankstructure to highlight the ability of the bank structures to control theprint width, Lines having 1, 2, and 3 layers of silver nanoparticle inkwere printed and cured in the same manner as previously described. Arepresentational width of each line was measured by profilometry. Thewidths of the 1, 2, and 3 layer printed silver lines were 97 μm, 110 μm,and 121 μm respectively. As expected, the width of the printed silverlines increases with an increase in printed ink volume without thepresence of the fluoropolymer bank structure.

Thus, it has been demonstrated that the coffee stain structure of afluoropolymer bank material can be utilized to fully contain printedsilver lines of equal width and various heights.

FIG. 11 is a flowchart illustrating a method for controlling printed inkhorizontal cross-sectional areas using fluoropolymer templates. Althoughthe method is depicted as a sequence of numbered steps for clarity, thenumbering does not necessarily dictate the order of the steps. It shouldbe understood that some of these steps may be skipped, performed inparallel, or performed without the requirement of maintaining a strictorder of sequence. Generally however, the method follows the numericorder of the depicted steps. The method starts at Step 1100.

Step 1102 provides a substrate. Step 1104 forms a fluoropolymer templateoverlying the substrate, the fluoropolymer template having a horizontalfirst cross-sectional dimension. For example, Step 1104 may form afluoropolymer template having a coffee stain pattern in the firstcross-sectional dimension. In another aspect, the fluoropolymer templatehas a water contact angle of greater than or equal to 90 degrees. Step1106 prints a primary ink overlying the fluoropolymer template having ahorizontal second cross-sectional dimension less than the firstcross-sectional dimension. In one aspect, forming the fluoropolymertemplate in Step 1104 includes forming a fluoropolymer line having atemplate length greater than a template width, where the template widthis the first cross-sectional dimension, Then, printing the primary inkin Step 1106 includes printing a primary ink line having an ink lengthgreater than an ink width, where the ink width is the secondcross-sectional dimension.

In one aspect, printing the primary ink line in Step 1106 includesprinting a plurality of primary ink layers, each primary ink layerhaving an ink width less than the template width. In another aspect.Step 1106 prints each overlying primary ink layer prior to solvents ineach underlying primary ink layer evaporating. In yet another aspect,Step 1106 increases the vertical average height of a combined layer inkline following the printing of each successive primary ink layer.Further, the average height is increased without increasing the inkwidth. In one aspect, increasing the average height of the combinedlayer ink line following the printing of each successive primary inklayer includes creating an increasing more pronounced coffee stainpattern in the ink width cross-section following the printing of eachsuccessive primary ink layer.

In one variation, Step 1106 prints a plurality of primary ink linesincluding electrically conductive particles. Step 1108 increases theoverall electrical conductance of the combined layer ink line followingthe printing of each successive primary ink layer. In this aspect, Step1104 may form a fluoropolymer line having a template width of 3 micronsor less.

In one aspect, forming the fluoropolymer template overlying thesubstrate in Step 1104 includes forming a fluoropolymer template havinga surface energy. Then, printing the primary ink having the secondcross-sectional dimension in Step 1106 includes the secondcross-sectional dimension being responsive to the fluoropolymer templatesurface energy.

A printed ink structure has been provided with a method for controllingthe widths of printed line structures. Examples of particular materialand process steps have been presented to illustrate the invention.However, the invention is not limited to merely these examples. Othervariations and embodiments of the invention will occur to those skilledin the art.

We claim: 1-12. (canceled)
 13. A printed ink structure with a controlledhorizontal cross-sectional area, the printed ink structure comprising: asubstrate; a fluoropolymer template overlying the substrate, thefluoropolymer template having a horizontal first cross-sectionaldimension with a concave top surface; and, a primary ink structureoverlying the fluoropolymer template having a horizontal secondcross-sectional dimension less than the first cross-sectional dimension.14. The printed ink structure of claim 13 wherein the fluoropolymertemplate has a template length greater than a template width, and wherethe template width is the first cross-sectional dimension; and, whereinthe primary ink structure has an ink length greater than an ink width,and where the ink width is the second cross-sectional dimension.
 15. Theprinted ink structure of claim 14 wherein the primary ink line is formedfrom a plurality of primary ink layers, each primary ink layer having anink width less than the template width.
 16. The printed ink structure ofclaim 15 wherein a vertical average height of an (n+1)th primary inklayer is greater than the average height of an nth primary ink layer.17. The printed ink structure of claim 16 wherein the ink width of the(n+1)th primary ink layer is equal to the ink width of the nth primaryink layer,
 18. The printed ink structure of claim 16 wherein a coffeestain pattern in the (n+1)th primary ink layer is more pronounced thanthe coffee stain pattern in the nth primary ink layer, where a coffeestain pattern is defined as a layer having vertical zero thicknessedges, bank structures between the zero thickness edges having avertical bank thickness, and a well between the bank structures having avertical well thickness less than the bank thickness and greater thanthe zero thickness.
 19. The printed ink structure of claim 15 wherein afirst primary ink structure with (n+1) conductive ink layers has ahigher electrical conductance than a second primary ink structure with nconductive ink layers.
 20. The printed ink structure of claim 13 whereinthe fluoropolymer template has a coffee stain pattern in the firstcross-sectional dimension. where a coffee stain pattern is defined as alayer having vertical zero thickness edges, bank structures between thezero thickness edges having a vertical bank thickness, and a wellbetween the bank structures having a vertical well thickness less thanthe bank thickness and greater than the zero thickness.